Low-Noise High Efficiency Bias Generation Circuits and Method

ABSTRACT

Embodiments of signal bias generators and regulators are described generally herein. Other embodiments may be described and claimed.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit under 35 U.S.C. §119 (e) of U.S.Provisional Application No. 61/371,652, filed Aug. 6, 2010, entitled“Low-Noise High Efficiency Bias Generation Circuits and Method”, andU.S. Provisional Application No. 61/372,086, filed Aug. 9, 2010,entitled “Low-Noise High Efficiency Bias Generation Circuits andMethod”; and this application is related to commonly-assigned andco-pending U.S. application Ser. No. 13/054,781, filed Jan. 18, 2011,and entitled “Low-Noise High Efficiency Bias Generation Circuits andMethod”, said U.S. application Ser. No. 13/054,781 being the U.S.National Stage Filing pursuant to 35 U.S.C. §371 of InternationalApplication Number PCT/US2009/004149 filed Jul. 17, 2009 (published byWIPO Jan. 21, 2010, as International Publication Number WO 2010/008586A2), which application claims priority to U.S. application Ser. No.61/135,279 filed Jul. 18, 2008 and entitled “Low Noise Charge Pump withCommon-Mode Tuning Op Amp”, and the contents of all of theabove-referenced provisional applications and the co-pending 13/054,781application are incorporated by reference herein in their entirety.

TECHNICAL FIELD

Various embodiments described herein relate generally to bias signalgenerators and regulators including systems, and methods used in biasregulators.

BACKGROUND INFORMATION

It may be desirable to provide stable voltage and current signals to avariable load device, the present invention provides such signals.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified block diagram of bias signal generationarchitecture according to various embodiments.

FIG. 2A is a simplified block diagram of a base bias signal generationmodule according to various embodiments.

FIG. 2B is a simplified diagram of a current source module according tovarious embodiments.

FIG. 2C is a simplified diagram of a current sink module according tovarious embodiments.

FIG. 3 is a block diagram of a positive voltage signal generation moduleaccording to various embodiments.

FIG. 4 is a block diagram of a negative voltage signal generation moduleaccording to various embodiments.

FIG. 5A is a block diagram of a voltage regulation module (VRM)according to various embodiments.

FIG. 5B is a simplified diagram of a voltage regulation module (VRM)according to various embodiments.

FIG. 6A is a block diagram of a bandgap reference module (BRM) accordingto various embodiments.

FIG. 6B is a simplified diagram of a bandgap reference module (BRM)according to various embodiments.

FIG. 7A is a block diagram of a reference voltage and current generatormodule (RVCGM) according to various embodiments.

FIG. 7B is a simplified diagram of a reference voltage and currentgenerator module (RVCGM) according to various embodiments.

FIG. 8 is a simplified diagram of a start algorithm according to variousembodiments.

FIG. 9A is simplified diagram of differential oscillator architectureaccording to various embodiments.

FIG. 9B is simplified diagram of a differential oscillator according tovarious embodiments.

FIG. 9C is simplified diagram of a differential oscillator bufferaccording to various embodiments.

FIG. 10 is simplified diagram of a symmetrical active resistor accordingto various embodiments.

FIG. 11A is simplified diagram of a P-bias voltage tracker according tovarious embodiments.

FIG. 11B is simplified diagram of a N-bias voltage tracker according tovarious embodiments.

FIG. 12 is simplified diagram of a positive voltage control signalgeneration module (VCSGM) according to various embodiments.

FIG. 13 is simplified diagram of a positive voltage charge pumpgeneration module (PVCPGM) according to various embodiments.

FIGS. 14A-14D are simplified diagrams of a negative voltage controlsignal generation module (NCSGM) 410 according to various embodimentsand the various components.

FIG. 15 is simplified diagram of a negative voltage charge pumpgeneration module (NVCPGM) 440 according to various embodiments.

DETAILED DESCRIPTION

FIG. 1 is a simplified block diagram of bias signal generationarchitecture (“BSGA”) 10 according to various embodiments. The BSGA 10includes a base bias signal generator module (“BBSGM”) 100, adifferential oscillator module (“DOM”) 200, a positive voltage chargepump module (“PVCPM”) 300, a negative voltage charge pump module(“NVCPM”) 400, a positive voltage clamping module (“PVCM”) 15, anegative voltage clamping module (“NVCM”) 17, a power supply module 18,and a switching module 22. The power supply module 18 may provide avariable power supply signal VDD and the module 18 may include one ormore batteries, capacitors or other electrical energy generationelements. The PSM 18 may be designed to supply a VDD signal having apredetermined voltage or current levels. The energy generation elementsperformance may vary as a function of temperature, load, age, anddepletion level. For example, a single cell battery may initial providea signal having a voltage level of about 4 volts and may degrade to lessthan 2 volts as the battery depletes and temperature or load fluctuates.

The BSGA 10 generates one or more signals VDD_LS, VSS for the switchingmodule 22 where VDD_LS may be a positive rail supply signal and the VSSmay be a negative rail supply signal. The load from the switching module22 generally varies significantly as the module performs one or moreswitching events. For example, a switching module 22 including a radiofrequency (RF) switch may have a nominal load between switching eventsand then a significant load with a quick rise time for the respectiveload, IN_SIGNAL. The BSGA 10 should be able to meet the loadrequirements of the switching module 22 while receiving a varying supplysignal VDD from one or more power supply modules 18. Further, the BSGA10 should perform these functions using minimal energy (efficient powerconsumption) and provide little or no undesirable noise on the loadssignals VDD_LS and VSS.

In an embodiment, the base bias signal generator module (“BBSGM”) 100,the differential oscillator module (“DOM”) 200, the positive voltagecharge pump module (“PVCPM”) 300, the negative voltage charge pumpmodule (“NVCPM”) 400, the positive voltage clamping module (“PVCM”) 15,and the negative voltage clamping module (“NVCM”) 17 operate in whole orpart to receive the VDD signal from the PSM 18 and efficiently generatethe signals VDD_LS and VSS. The BBSGM 100 may receive a variable voltagesignal VDD from PSM 18 and generate a plurality of stable bias signalsBIASP1, BIASP2, BIASN1, BIASN2, and an internal, positive rail supplyVDD_INT. In an embodiment, the BBSGM 100 may function with a receivedVDD signal having a voltage level from 2.3 volts to 5.5 volts.Accordingly, the BBSGM 100 may effectively regulate the power supplymodule 18 external supply signal VDD.

As shown in FIG. 1, the PVCM 15 may include several P-type diodes 11A,11B, and resistors 12A, 12B, 12C. In an embodiment, the signal VDD_LS istargeted to be about +3.4 Volts. Diode 11A tightly couples the nodeVDD_LS to the node VPOS (the output of the positive voltage charge pumpmodule 300) during a switching event. The diode 11A may effectivelybypass the resistors 12A, 12B, 12C and any capacitance during aswitching event. In an embodiment, the diode 11A may have no voltagedrop (0 volts across it) during steady state. VPOS provides the positivevoltage signal to PVCM 15. The resistors 12A, 12B, and 12C may filterand limit the current draw from VPOS to VDD_LS.

The diode 11A may be forward biased when the voltage level of VPOS isgreater than the voltage level of VDD_LS. Diode 11B is forward biasedwhen the voltage level of the signal VDD_INT is greater than the voltagelevel of VDD_LS. Diode 11B may effectively clamp or provides a floorvalue for VDD_LS given the voltage level of VDD_INT is nominally 2.3Volts. In an embodiment, the diodes 11A, 11B may be CMOS field-effecttransistor (FET)s. Diode 11A may have a width of about 10 microns, alength of about 0.4 microns and number of channels (mt)=10, denoted as10/0.4/mt=10. Using this nomenclature, Diode 11B may be 10/0.4/mt=5 inan embodiment. Resistors 12A, 12B, 12C may have a width/length/resultantresistance where length and width are in microns and resistance is inKilo Ohms. Using this nomenclature in an embodiment resistors 12A, 12B,12C may be about 10.7/1.4/19.98, 5.3/1.4/9.982, 2.8/1.4/5.353,respectively.

As discussed below with reference to FIG. 2A, the BBSGM 100 may includea Voltage Regulator Module 110 (VRM), a Bandgap Reference Module 140(BRM), a Reference Voltage and Current Generator Module 170 (RVCGM), anda Startup and Standby Module 190 (SSM). The VRM 110 may receive thevariable voltage external signal VDD and generate a stable internalvoltage signal VDD_INT_SB. The BRM 140 may receive the internal signalVDD_INT_SB and generate a stable reference signal (VBG). The ReferenceVoltage and Current Generator Module 170 (RVCGM) may receive the VBG andVDD_INT_SB signal and generate a first and second bias signal for P-typedevices (BIASP1, BIASP2) and a first and second bias signal for N-typedevices (BIASN1, BIASN2).

The DOM 200 may receive the stable bias signals BIASP1, BIASP2, BIASN1,BIASN2, and internal, positive rail supply VDD_INT generated by BBSGM100 and generate one or more oscillation or clock signals OSC1, OSC2. Inan embodiment, the DOM 200 may be a capacitively coupled three stagedifferential inverter ring as shown in FIG. 9A. In an embodiment, eachstage 203 A may use coupling capacitors to separately drive P-MOS 204 Eand N-MOS 204 F devices (as shown in FIG. 9B). Other embodiments arealso possible without differential inverters, by providing asingle-ended to differential conversion in the output stage (not shown).

The PVCPM 300 may receive the stable bias signals BIASP1, BIASP2, VBGand internal, positive rail supply VDD_INT generated by BBSGM 100, andOSC1, OSC2 from the DOM. The PVPCM 300 provides a positive voltagesignal output VPOS. In an embodiment, the switching module 22 mayreceive three voltage signals, a ground GND, a positive voltage signalVDD_LS, and a negative voltage signal VSS. The PVCPM VPOS signalprovides for the regulated positive rail voltage VDD_LS. In anembodiment the signal VDD_LS is targeted to be about 3.4 volts.Switching modules 22 commonly include a large capacitance that must bedriven within a strict time frame (within 5 us in an embodiment).

In an embodiment, the VSS signal recovery time (after a switching event)may affect the harmonic knee point (HKP) of a signal IN_SIGNAL switchedby the switching module 22 to generate OUT_SIGNAL. In an embodiment, theVDD_LS signal recovery time after a switching event may affect theinsertion loss of a signal IN_SIGNAL switched by the switching module 22to generate OUT_SIGNAL. A VDD_LS signal fast settling time may reducethe switching module 22 switched signal IN_SIGNAL insertion loss. TheNVCPM 400 generates a negative voltage signal VNEG. As noted, the NVCPM400 ideally settles quickly (the VNEG voltage level is back to desiredlevel(s)) after a load event (switching event in an embodiment)). Asnoted the signal settling time may affect the HKP of the switchingmodule 22.

As shown in FIG. 1, the NVCM 17 may include a P-type diode 11C, andresistors 12D, 12E, 12F. In an embodiment, the signal VSS is targeted tobe about −3.4 Volts. Diode 11C may tightly couple the node VSS to thenode VNEG (the output of the negative voltage charge pump module 400)during a switching event. The diode 11C may effectively bypass theresistors 12D, 12E, 12F and any capacitance generated during a switchingevent. In an embodiment, the diode 11C may have no voltage drop (0 voltsacross it) during steady state. VNEG provides the negative voltagesignal to VSS. The resistors 12D, 12E, and 12F may filter and limit thecurrent draw from VNEG to VSS. The diode 11C may be forward biased whenthe voltage level of VNEG is less than the voltage level of VSS. In anembodiment, the diode 11C may be a CMOS field-effect transistor (FET).The Diode 11C may be about 10/0.4/mt=10. Resistors 12A, 12B, 12C mayhave a width/length/resultant resistance of about 10.7/1.4/19.98,5.3/1.4/9.982, and 2.8/1.4/5.353, respectively.

FIG. 2A is a simplified block diagram of a Base Bias Signal GenerationModule 100 according to various embodiments. As noted the BBSGM 100 mayinclude a Voltage Regulator Module 110 (VRM), a Bandgap Reference Module140 (BRM), a Reference Voltage and Current Generator Module 170 (RVCGM),and a Startup and Standby Module 190 (SSM). The VRM 110 receives theexternal, variable voltage signal VDD and regulates the voltage level tobe about 2.3 volts in an embodiment. The VRM 110 provides the regulatedvoltage VDD_INT_SB to the BRM 140 and the RVCGM 170.

The BRM 140 receives the reference voltage VDD_INT_SB signal andgenerates a VBG (bandgap voltage) signal of about 1.16 V (in anembodiment) and passes the reference signal VBG to the RVCGM 170 and theVRM 110. The VRM 110 may use the VBG signal to determine and set thelevel of the VDD_INT_SB. In an embodiment the VBG signal level is afunction of physical diode element formation and resistor combinationthat comprises the BRM 140.

The RVCGM 170 receives the VBG signal and the VDD_INT_SB signal andgenerates a reference current of about 1.2 uA (in an embodiment) andgate bias reference voltages BIASP1, BIASP2, BIASN1, and BIASN2. FIG. 2Bis a simplified diagram of a current source module 142 according tovarious embodiments. The current source CS-P 142 includes a plurality ofcascaded P-type field-effect transistor (FET)s 141A, 141B. When the biassignals BIASP1 and BIASP2 are stable, the current generated by thecascaded FETs 141A, 141B is also stable, constant, and about 1.2 uA inan embodiment. In an embodiment, the bias gate signal BIASP1 sets thelevel of the basis current. BIASP2 provides higher output impedance tothe CS-P 142. In an embodiment, the P-FETs 141A, 141B may be about4/2/mt=1, 4/2/mt=1 respectively.

FIG. 2C is a simplified diagram of a current sink module CS-N 172according to various embodiments. The current source CS-N 172 includes aplurality of cascaded N-type field-effect transistor (FET)s 171A, 171B.When the bias signals BIASN1 and BIASN2 are stable, the current drawn bythe cascaded FETs 171A, 171B may also be stable, constant, and about 1.2uA. In an embodiment, the N-FETs 171A, 171B may be about 4/2/mt=1,4/2/mt=1 respectively. The use of the CS-P and CS-N and respective gatebias signals BIASP1, BIASP2, BIASN1, BIASN2 may reduce the usage ofresistors and transistors to control current source and sink levels.

In an embodiment the CS-P 142 and the CS-N 172 are used in operationalamplifiers (OPAMP) and operational trans-conductance amplifiers (OTA) inthe VRM 110, the BRM 140, the DOM 200, the PVCPM 300, and the NVCPM 400.The RVCGM 170 receives the VBG signal and may employ a known resistanceto generate a signal with a known current, IREF. The RVCGM 170 alsogenerates the gate bias voltages BIASP1, BIASP2, BIASN1, and BIASN2.

In an embodiment the BBSGM 100 may also include startup and standbycomponents 190, 120, 150, 180. As noted in an embodiment the VRM 110,the BRM 140, and the RVCGM 170 may provide reference signals to othermodules DOM 200, PVCPM 300, NVCPM 400. Similarly the BRM 140 provides areference signal to the VRM 110 and the RVCGM 170. During a standbycondition or startup, the SSM 190 may suppress the VDD_INT signal tostop operation of the DOM 200, PVCPM 300, NVCPM 400 modules. Such aninterruption of the VDD_INT signal may reduce the power consumption ofthe architecture 10. The BBSGM 100 may still operate in order to receiveand process standby and wake signals.

FIG. 3 is a block diagram of a PVCPM 300 according to variousembodiments. The PVCPM 300 may include a control module 310 and a chargepump module 340. The control module 310 may receive the gate biassignals BIASP1, BIASP2, internal voltage signal VDD_INT, VBG and VDD_LS,and generate a control signal POS_CP_VDD representing a desired voltagesignal level. The charge pump module 340 may receive the POS_CP_VDDsignal and clock signals OSC1, OSC2 and generate a positive voltagesignal VPOS.

FIG. 4 is a block diagram of a NVCPM 400 according to variousembodiments. The NVCPM 400 may include a control module 410 and a chargepump module 440. The control module 410 may receive the gate biassignals BIASP1, BIASP2, BIASN1, BIASN2, internal voltage signal,VDD_INT, VBG and VSS and generate a control signal NEG_CP_VDDrepresenting a desired voltage signal level. The charge pump 440 modulemay receive the NEG_CP_VDD signal, and clock signals OSC1, OSC2, andgenerate the negative voltage signal VNEG.

FIG. 5A is a block diagram of a voltage and current regulation module(VRM) 110 according to various embodiments. As shown in FIG. 5A, the VRM110 may include an OTA 114, an LDO 124, a voltage divider 121, a Schmitttrigger 112, and a standby-startup module 130. The voltage divider 121may receive the internal voltage signal VDD_INT_SB as a feedback signaland generate a voltage signal about ½ the voltage signal VDD_INT_SB (½VDD_INT) in one embodiment. The OTA 114 may receive the external voltagesignal VDD, the internal bandgap reference signal VBG, and a voltagereference (½ VDD_INT) equal to half of the internal voltage VDD_INT_SB.The OTA 114 determines the differential between the signal VBG and ½VDD_INT_SB. In an embodiment the VBG signal voltage level is about ½ thedesired internal voltage of the signal VDD_INT_SB. Accordingly, the OTAdifferential signal represents the difference between the desiredvoltage level and the current voltage level of the VDD_INT_SB signal.

The OTA 114 generates an LDO control signal where the signal varies as afunction of the determined voltage level differential signal. In anembodiment the low drop out (“LDO”) module 124 receives the VDD signaland generates the internal voltage signal VDD_INT_SB based on the LDOcontrol signal generated by the OTA 114. The Schmitt trigger 112 may beset to trip when the BIASP1 signal reaches a desired voltage level. TheBIASP1 desired predetermined voltage level may indicate that the BBSGM100 is fully operational after a startup or standby event. Thestandby-startup module 130 may use the trigger 112 signal to determinethe operational status of VRM 110 after a restart or standby event.

FIG. 5B is a simplified diagram of a voltage and current regulationmodule (VRM) 110 according to various embodiments. As shown in FIG. 5B,the VRM 110 may include an OTA 114, a low drop out FET (LDO) 124, avoltage divider 121, and resistors 122. The OTA 114 may include the CS-N172 to create a current sink of about 1.2 uA in an embodiment. The OTA114 also includes cascade intrinsic N-type FETs 117A, 117B, thicker filmregular type P-type FETs (TRP) 118A, 118B, and regular type N-type FET(RN) 116A, 116B. The FETs 118A, 118B, 116A, 116B form a trans-impedanceamplifier that determines the difference between the inputs at the gatesof 116A, 116B.

The TINs 117A, 117B may be coupled at their respective gates. Thereference signal VBG (about 1.16 V in an embodiment) may be received atgate 116B. The other gate 116A receives the divided voltage signal ½VDD_INT (half of the internal voltage signal VDD_INT_SB in anembodiment) from the voltage divider 121. In an embodiment, the TRP-FETs118A, 118B may be about 4/2/mt=1, 4/2/mt=1, respectively. The TIN-FETs117A, 117B may be about 4/1/mt=1, 4/1/mt=1, respectively. The RN-FETs116A, 116B may be about 4/2/mt=2, 4/2/mt=2, respectively. The cascadecurrent sink N-FETs 115A, 115B may be about 4/2/mt=1, 4/2/mt=1,respectively as noted above.

The voltage divider 121 may include several resistors 123A, 123B. Whenthe resistance of the resistors 123A, 123B are about equal, the gate of116A may be about ½ of the internal voltage signal VDD_INT_SB. In anembodiment the resistor 123A may have a resistance of about 604 Kohmsand may include multiple, coupled resistors including resistors that maybe about 13.5/1.4/50.34/ms=2, and 13.5/1.4/553.7/ms=22, respectively.The resistor 123B may have a resistance of about 604 Kohms and mayinclude multiple, coupled resistors including resistors that may beabout 13.5/1.4/25.17/ms=1, 13.5/1.4/75.51/ms=3, 13.5/1.4/302/ms=12, and13.5/1.4/201.4/ms=8, respectively.

The LDO 124 is a TRP receiving its gate signal from the OTA 114. The LDO124 generates or regulates the internal voltage signal VDD_INT_SB basedon the gate signal. In an embodiment, the LDO 124 TRP may be about10/0.5/mt=8. Accordingly, the VRM 110 may receive an external signal VDDhaving a voltage range of 2.3 to 5.5 V and provide an internal voltagesignal that is about 2.3 volts in an embodiment. The cascaded TINs 117A,117B, may break up the drain voltage of the differential pair 116A, 116Bfrom the differential load 118A, 118B to develop output voltage on theOTA 114. The TRP pair 118A, 118B may form a current mirror differentialload. In an embodiment the OTA 114 may effectively be a differentialpair with active load that may handle higher voltage given VDD may vary.The resistors 121A, 121B may be about 9.5/1.4/35.52/ms=2 and50.9/1.4/377.7/ms=4, respectively.

FIG. 6A is a block diagram of a bandgap reference module (BRM) 140 andFIG. 6B is a simplified diagram of the BRM 140 according to variousembodiments. As shown in FIGS. 6A, 6B, the BRM 140 may include an OTAmodule 150, a bandgap module 160, and a standby-startup module 164. Thebandgap module 160 may include resistors 161A, 161B, and 161C and diodes162A, 162B, 162C having different channel widths to generate a voltagedifferential that is measured by the OTA 150. The diodes 162A, 162B maybe about 1.4/1.6/mp=1, 34.2/1.6/mp=6, and 14.4/1.6/mp=1 respectively inan embodiment. The OTA 150 may use the determined differential togenerate the reference voltage signal VBG (about 1.16 V in anembodiment).

In an embodiment the diodes 162A, 162B, 162C may both be formed in asingle CMOS wafer and due to similar channel lengths (1.6 um in anembodiment) operational variance due to temperature and wafer processingmay not change the effective differential (bandgap) between the diodes162A, 162B, 162C. Accordingly, the related diode 162A, 162B, 162Cbandgap may be stable from wafer to wafer and temperature independent.In an embodiment, the resultant VBG level is thus known based on theknown diode characteristics (as known by the diode formation process andmaterials).

The standby-startup module 164 may include an RN FET 153C that bypassesthe diodes 162B, 162C based on the state of the START_FLAG. RN FET 153Cmay be about 4/1/mt=1 in an embodiment. As noted the bandgap module 160may also include the resistors 161A, 161B, and 161C as shown in FIG. 6B.The resistors 161B, 161C may be about 13.4/1.4/199.8/ms=8 and13.4/1.4/224.8/ms=9, respectively. The resistor 161A may include tworesistors in series and the resistors may be about 13.4/1.4/424.7/ms=17and 13.4/1.4/24.98/ms=1, respectively.

In an embodiment the OTA 150 may include two current sources CS-P 142including cascaded FETs RP 151A, 151B and 151C, 151D. The FETs RP 151A,151B, 151C, 151D may each be about 4/2/mt=1. In an embodiment, each CS-P142 may provide a current source of about 1.2 uA. The RP pair 152A, 152Band RN pair 153A, 153B may form an amplifier. The amplifier may receivethe constant current source from the CS-P (formed from RP pair 151A,151B) and the differential signal from the diodes 162A, 162B andresistor 161C. Cascaded FETs IN 153F and RN 153E may be coupled to thesecond current source CS-P 142. The FETs 152A, 152B may each be about10/2/mt=4, FETs 153A, 153B may each be 10/4/mt=2, FET 153F may be about7.5/0.5/mt=1, and FET 153E may be about 10/0.9/mt=1. The OTA 150 alsoincludes FET IN 153D. The standby-startup module 164 may further includean RN FET 153G that bypasses the RN FET 153B based on the state of theSTART FLAG. RN FET 153G may be about 3/1/mt=1 in an embodiment.

The bandgap reference module 140 may also include a standby-startupmodule 164. The startup module 164 may include cascaded FETs IN 166A,FET RP 166B where the gates of the respective FETs may receive the VDDINT_SU and IREF_SU startup signals and FET IN 153D which serves as anoutput buffer whose gate is coupled to the drain of the FET RP 166B andthe output of the second stage amplifier of the op-amp consisting of153E/F and 151C/D. The FETs IN 166A, RP 166B, IN 153D may be about4/1/mt=1, 4/1/mt=1, and 14.6/0.5/mt=1, respectively. The startup module164 ensures the VBG signal reaches the appropriate operational level.VDD_INT_SU is based on VDD_INT and IREF_SU is based on IREF. As notedthe standby-startup module 164 also includes RN FETs 153C and 153G.

FIG. 7A is a block diagram of a reference voltage and current generatormodule (RVCGM) 170 and FIG. 7B is a simplified diagram of the RVCGM 170according to various embodiments. As shown in FIGS. 7A, 7B, the RVCGM170 may include an OTA module 180, a current/bias voltage generationmodule (CBVGM) 192, and standby-startup module 188. The OTA 180 mayinclude a current sink CS-N 172 including cascaded TRN 181A, 181B. TheFETs TRN 181A, 181B may be about 4/2/mt=1, 4/2/mt=1, respectively. In anembodiment, the CS-N develops a current sink of about 1.2 uA. The RNpair 182A, 182B and TRP pair 183A, 183B form an amplifier coupled to theconstant current sink of CS-N 172 (formed from TRN pair 181A, 181B). TheFETs TRP 182A, 182B, 183A, 183B may each be about 4/2/mt=1,respectively.

In an embodiment the OTA 180 may determine the difference of the VBGsignal and IVREF signal generated by the LDO 185 and resistor 186(current across the resistor 186 where the LDO 185 is a current source).The LDO 185 includes cascaded TRP 184A, 184B. In an embodiment the FETsTRP 184A, 184B may be about 4/2/mt=2, and 4/2/mt=2 respectively (notethat number of channels is 2—twice the number of the current source 142). Accordingly, the LDO 185 may generate a current source of about 2.4uA in an embodiment when BIASP1 and BIASP2 are steady state. Theresistor 186 may be about 494 K-ohms in an embodiment. Given the LDO 142is generating a current of about 2.4 uA at steady state and theresistance of 494 Kohms, the voltage level of the signal or point IVREFmay be about 1.16 Volts at steady state. The VBG signal voltage levelmay be about 1.16 volts at steady state and is generated by the BRM 140.The OTA 180 regulates the generation of the IVREF signal using the VBGreference signal and effectively the four gate bias signals BIASN1,BIASN2, BIASP1, and BIASP2.

In an embodiment, the LDO 185 may provide current IREF to resistor 186to generate the corresponding voltage signal IVREF. The CBVGM 192generates the gate bias signals BIASP1, BIASP2, BIASN1, and BIASN2. Atsteady state (when IVREF voltage level is about 1.16 Volts (receiving2.4 uA from 185 ), BIASN1 is about the threshold level of the TRN 187B(about 0.7 V in an embodiment). BIASN2 is greater than BIASN1 due tocascaded TRN 187A and TRN 189 (about 200 mV greater in an embodiment or0.9 V). BIASP1 is about one threshold of the TRP 186A below the supplyrail VDD_INT (about 2.3 V less 0.7V=1.6V). BIASP2 is lower than BIASP1due to TRP 186 E (about 200 mV less in an embodiment, 1.4V). It is notedthat TRP 186A and TRP 186B form a current source 186C that generates aconstant current of 1.2 uA when the gate bias signals BIASP1 and BIASP2are at steady state (1.6 Volts and 1.4 Volts in an embodiment).

It is noted that the TRP 186A has a different Vgs (Voltage Gate toSource) than TRP 186E due to their different physical configurations(TRP 186A may be have a width/length of about 4/2 (microns), mt=1 andTRP 186 E may have a width/length of about 2/8 (microns), mt=1, and TRP186B may be have a width/length of about 4/2 (microns), mt=1. Similarly,the TRN 189 may have a different Vgs than TRN 187B due to differentphysical configurations (TRN 187B may be have a width/length of about4/2 (microns) (mt=1 ), TRN 189 may have a width/length of about 2/8(microns) (mt=1 ), and 187A may be have a width/length of about 4/2(microns) (mt=1 ). The CBVGM 192 also includes a current source 142formed by TRP 186C and TRP 186D coupled to TRN 187C and TRN 187D whereeach may be about 4/2/1 in an embodiment.

In an embodiment the BBSGM 100 modules rely on the gate bias signalsBIASN1, BIASN2, BIASP1, and BIASP2 and reference signals (VBG) generatedby the various modules 110, 140, and 170 to operate at steady state. Theremaining modules of the architecture 10 also need steady state gatebias signals BIASN1, BIASN2, BIASP1, and BIASP2. Given theinterdependence between the BBSGM 100 modules 110, 140, 170, a startupor standby wake method 142 (FIG. 8) may be employed in an embodiment toenable the BBSGM 100 to reach steady state. Further, startup of BBSGM100 (from a cold start or standby) may be controlled by additionalstartup/standby modules as noted above where the modules may employ themethod or algorithm 142. FIG. 8 is a simplified diagram of a BBSGM 100activate (from cold start or standby) algorithm 142 according to variousembodiments that may be employed in the BBSGM 100. During a cold startor standby, capacitors of the BSGA 10 may be discharged and externalrail supply VDD may be rising. In the process 142, VDD_INT_SB (internalvoltage standby) may be pulled up as the external voltage VDD rises(activity 142). In an embodiment the VRM 110 of BBSGM 100 shown in FIG.5B may include resistors 121A, 121B of standup module 122 that pull upVDD_INT_SB as VDD rises (increase voltage level as current draw isincreased in the OTA 114).

As VDD_INT_SB starts to rise, the RVCGM 170 starts to function andgenerate the gate bias signals BIASN1, BIASN2, BIASP1, BIASP2, which areused by the BRM 140, the RVCGM 170, and the VRM 110 (activity 143 ). Inan embodiment the BRM 140 may not generate a steady state band-gapsignal VBG until the internal voltage signal VDD_INT is greater thanthresholds 166A, 166B of activate (standby-startup) module 164(activities 144, 145 ). In particular, FETs IN 166A, and RP 166B form avalve that pulls up VBG to VDD_INT_SU during startup. VDD_INT_SU may beat ground (GND) at startup. As noted above the FETs IN 166A, RP 166B maybe about 4/1/mt=1, 4/1/mt=1, and 166A may have a lower threshold andthus lower voltage drop. At steady state, the voltage level of thesignals VDD_INT_SU and IREF_SU are similar so the valves 166A, 166B maybecome closed or inactive.

Thereafter, the VBG signal may rise to its nominal level (about 1.16 Vin an embodiment) (activity 146 ) as the BRM 140 starts to operate(activity 145). The RVCGM 170 OTA 180 may operate and then generate theIREF signal (current level monitored) and corresponding IVREF signal(voltage level monitored) to be compared against the VBG signal voltagelevel (activity 147). In an embodiment, activate or startup valves 189A,189B may pull up BIASP1 and BIASP2 during startup. In an embodiment thestartup valves 189A, 189B may each include cascaded FETS TRN and IPwhere the FETS TRN and IP (intrinsic P-type) may be about 2/1/mt=1,2/1/mt=1, respectively. The TRN gates of 189A, 189B may receive the VBGsignal and the IP gates of modules 189A, 189B may be coupled to thesignal IVREF. At steady state the voltage level of the signals IVREF andVBG are similar so the valves 189A, 189B may become closed or inactive.

The startup flag used in the startup modules 190, 120, 150, 180 may beset to end operation of these modules (activity 148 ) when the RVCGM 170reaches steady state (activity 147). When the gate bias signals BIASN1,BIASN2, BIASP1, and BIASP2 and reference signal VBG are steady state,the VRM 110 may effectively generate a steady state signal VDD_INT froma variable voltage level input signal (VDD external) where the VDD_INTsignal may be used by other BSGA 10 modules (activity 149 ). In anembodiment the Schmitt trigger 112 may receive the bias signals BIASP1,BIASP2 and limit the operation of the OTA 114 operation and the LDO 124until the trigger 112 is tripped. Then the VRM 110 may effectivelygenerate the VDD_INT signal from a variable voltage external VDD signal.When process 142 is complete, the gate bias signals BIASN1, BIASN2,BIASP1, and BIASP2, the reference signal VBG, and the VDD_INT may havesteady values that may be used by the other BSGA 10 modules. Given thisconfiguration the other modules may be designed based on theavailability of constant gate bias signals and voltage supply signals.

As noted the BSGA 10 may provide signals VDD_LS and VSS having known,steady voltage levels to a switching module 22. BSGA 10 may be requiredto maintain the signals VDD_LS, VSS voltage levels during switchingevents. In an embodiment, BSGA 10 may employ charge pumps modules 300,400 (positive and negative) to ensure the voltage levels of the signalsVDD_LS and VSS remain constant during loading events. The BSGA 10 mayemploy a differential oscillator module 200 to control operation of thecharge pump module 300, 400 in an embodiment.

FIG. 9A is simplified diagram of differential oscillator module (DOM)200 according to various embodiments. As shown in FIG. 9A the DOM 200may include a plurality of ring oscillators 203A and an oscillatoroutput buffer 203B, resistors 201A, 201B, and capacitors 202A to 202F.In an embodiment DOM 200 may receive gate bias signals BIASP1, BIASP2,BIASN1, BIASN2, and internal voltage signal VDD_INT (generated by BBSGM100 ) and generates differential oscillator or clock signals OSC1, OSC2.In an embodiment DOM 200 may be a three stage, current starved, ACcoupled oscillator. In an embodiment the resistors 201A, 201B may beabout 96.2/1.4/356.6/ms=2 and 144.3/1.4/267.4/ms=1, respectively. Thecapacitors 202A to 202F may be about 18/8.9/941.6 fF/mp=1,24.1/8.9/1.259 pF/mp=1, 0.800/6.9/37 fF/mp=1, 0.500/6.25/22.73 fF/mp=1,17/9.6/958.7 fF/ mp=1, 22.7/9.6/1.278 pF/ mp=1, respectively. It isnoted that during standby or startup, VDD_INT, BIASN1, BIASN2, BIASP1,and BIASP2 are at GND so DOM 200 may not function during standby orstartup.

In an embodiment, each ring oscillator stage 203A contains single endedinverters, side-by-side coupled in anti-phase with other stage 203 As.In order to control oscillation frequency, a current starved scheme maybe employed where the inverters are not directly coupled to supply railsbut are coupled to the supply rails via current sources or sinks (205A,206A in FIG. 9B). FIG. 9B is simplified diagram of a differentialoscillator cell 203A according to various embodiments. The cell 203Aincludes an inverter 208A formed by a TRP 204E and TRN 204F pair thatare coupled by an anti-phase inverter 209 to another inverter 208B alsoformed by a TRP 204E and TRN 204F pair. The anti-phase inverter 209includes an inverter 209A formed by a TRP 204E and TRN 204F pair andinverter 209B also formed by A TRP 204 E and TRN 204F pair.

The inverters 208A, 208B are each coupled to a current source CS-P 205A(formed by TRP pair 204B) and current sink CS-N 206A (formed by TRN pair204A). The combination of the CS-P 205A and CS-N 206A on each side ofthe inverters 208A, 208B starves the inverters 208A, 208B of current.The anti-phase inverter 209 (formed from inverters 209A, 209B) is alsocoupled to a current source CS-P 205B (formed by TRP pair 204D) andcurrent sink CS-N 206B (formed by TRN pair 204C). In an embodiment theCS-P 205A and CS-N 206A current draw is four times greater than thecurrent draw of CS-P 205B and the CS-N 206B current, respectively. FETSTRP 204B and TRN 204A may be about 10/0.6/mt=1, in an embodiment. Thecurrent source 205A may generate about 1.2 uA and the current drain 206Amay draw about 1.2 uA (similar to 141A, 141B). FETS TRP 204E and TRN204F may be about 1.6/0.35/mt=1, in an embodiment. FETS TRP 204D and TRN204C may be about 2.5/0.6/mt=1, in an embodiment. The current source205B may generate about 0.3 uA and the current drain 206B may draw about0.3 uA.

In an embodiment, the threshold of TRP 204B is about 0.7V, which isabout the difference between the rail, VDD_INT (2.3 V) and BIASP1(1.6V). In an embodiment a differential ring cell 203A may not use thegate signals BIASN2 and BIASP2. In operation, an AC component of asignal is passed to the inverter gates 208A, 208B via inputs INP, INN.When the gate bias shifts, the P and N type devices (TRN and TRP) mayswitch operation to create oscillation. In an embodiment, capacitors211A may be about 8.8/4.4/232.3fF/mp=1 so only an AC component of thesignals INP, INN is passed to the inverters 208A, 208B gates. A DC biassignal is provided by BIASP1 and BIASN1 where any AC content on theBIASP1, BIASN1 signals is removed by active resistors 207 (describedbelow).

Further when one of CS-P 205A is operating the TRP 204B pair is activeand the respective TRN 204A pair and CS-N 206A are not active, currentis sourced to the respective output (OUTN or OUTP). Similarly, when oneof CS-N 206A is operating, the TRN 204A pair is active and therespective TRP 204B pair and the CS-P 205A are not active, current issinked to the respective output (OUTN or OUTP). Accordingly, adifferential ring cell 203A may create a trapezoidal waveform (linearincline and decline with flat tops). As noted, the anti-phase oranti-parallel inverters 209A, 209B are minor inverters compared to theinverter formed by 208A, 208B due to the ¼ current source and sink 205B,205A. In an embodiment, the inverters 208A may be coupled to theanti-parallel inverter complementary input. In an embodiment theoscillation frequency of the DOM 200 is about 8.2 MHz versus 3.6 MHz inother embodiments. The length of the FETs TRP 204B, 204D and TRN 204A,204C may be 0.6 um in an embodiment to increase the DOM 200 frequencyversus 1.0 um in another embodiment. The reduction of FET lengths from1.0 um to 0.6 um increases the core bias current by approximately 66% inan embodiment.

FIG. 9C is simplified diagram of a differential oscillator buffer 203Baccording to various embodiments. As show in FIG. 9C, the buffer 203Bincludes an inverter formed from 209C, 209D, current source CS-P 205Cand current sink CS-N 206C, active resistors 207, and capacitors 211B.Similar to differential ring cells 203A, differential ring buffer 203Bis AC coupled where a received signal (on INN and NP) is split (betweenAC and DC). The ABR 207 create a DC bias to drive TRP 204G and TRN 204Hdevices from the BIASP1 and BIASN1 gate bias signals while not passingany AC content on these signals. The inverters formed by 209C, 209Dperform current steering between the two current sources and theoutputs. When INN is above NP, the CS-N 206C sinks current from OUTPmaking it fall, and CS-P 205C sources current to OUTN making it rise.When IPP is above INN, the CS-N 206C sinks current from OUTN making itfall, and CS-P 205C sources current to OUTP making it rise.

In an embodiment the current sinks CS-N 206C and source CS-P 205C passthree times the current of the CS-N 206A and CS-P 205A to prevent shootthrough currents. The capacitors 202A to 202F shown in FIG. 9A preventpossible feedback to the BBSGM 100. FETS TRP 204J and TRN 204I may beabout 20/0.6/mt=2, in an embodiment. The current source 205C maygenerate about 3.6 uA and the current drain 206C may draw about 3.6 uA(three times the level of 205A, 206A). FETS TRP 204G and TRN 204H may beabout 4/0.35/mt=1 and 2/0.35/mt=1 in an embodiment. In an embodiment,capacitors 211B may be about 10/4.3/257.7 fF/mp=1 so only an ACcomponent of the signals INP, INN is passed to the inverters 209C, 209Dgates. The length of the FETs TRP 204J and TRN 204I may be 0.6 um in anembodiment to increase the DOM 200 frequency versus 0.8 um in anotherembodiment. The reduction of FET lengths from 0.8 um to 0.6 um increasesthe core bias current by approximately 33% in an embodiment.

FIG. 10 is simplified diagram of a symmetrical active bias resistor(ABR) 207 according to various embodiments. The ABR 207 may be used inplace of a large resistor to remove an AC component from the inputsignal and couple DC components of signals. In an embodiment, the ABR207 is symmetrical and can operate in either direction. As shown in FIG.10, an ABR 207 may include TIN 213A, 213B, TRN 214A, 214B, 215A, 215B,216A, 216B, and TIN 217A, 217B. The TIN's 217A, 217B source and drainare coupled to effectively form a switchable capacitor. In an embodimentthe TIN 213A, 213B may be about 1.4/0.5/mt=1, TRN 214A, 214B, 215A,215B, 216A, 216B may be about 1.4/2/mt=1, and TN 217A, 217B may also beabout 1.4/2/mt=1.

In operation NODEA and NODEB may effectively switch operation asfunction of whether the voltage level of NODEB is less than or greaterthan the voltage level of NODEA. In an embodiment an ABR 207 may be usedto bias a clock signal at a given DC bias. In this embodiment NODEA orNODEB is connected to a DC bias and the other of NODEA or NODEB isconnected to a clock side. The clock side signal includes a capacitivecoupled AC signal. For example, if an AC signal is coupled to NODEA anda DC bias is coupled to NODEB, then NODEA will have the same DC basis asNODEB. An ABR 207 may not affect the AC component of NODEA in theexample, but only pass a DC component from a NODEB signal to NODEA. Itis noted that the ABR 207 may very quickly track a DC bias between NODEAand NODEB given there is no RC time constant delay that may commonlyexists when a resistor is employed to create a DC bias.

In operation when an AC signal on NODEA is rising and its potential isgreater than NODEB the left side (A) of the ABR 207 is active oroperates. However, when an AC signal on NODEA is falling and itspotential is less than NODEB the right side (B) of the ABR 207 is activeor operates. As noted 217A, 217B are capacitors. As NODEA risesdisplaced currents are passed to TRN 214A and the gates of TRN 215A, TIN213A are also pulled up by the displacement current through thecapacitor 217A. TIN 213A is optional in an embodiment and providesadditional impedance if needed. In this example an AC path is presentfrom NODEA to NODEB via 214A and 217A. A DC path is formed from 213A and215A (from NODEA to NODEB). The DC path formed by TN 213A and TRN 215Aenables the ABR 207 to track DC bias changes quickly. The capacitance of217A, 217B adjusts the current tracking rate.

In an embodiment the ABR 207 is only affected by the respectivepotential levels of NODEA and NODEB. When the NODEA potential fallsbelow the NODEB potential, the diode 216A may operate to discharge thecapacitor 217A (the diode 216A becomes forward biased). Accordingly itmay be desirable to make the capacitance of 217A, 217B small to createsmall currents (losses) similar to a large resistor.

FIG. 11A is simplified diagram of a P-bias voltage tracker (P-VT) 349Aaccording to various embodiments. FIG. 11B is simplified diagram of anN-bias voltage tracker (N-VT) 349B according to various embodiments. Thetrackers 349A, 349B receive clock inputs CLK_N and CLK_P and act as aswitched capacitor circuit that generates a DC offset from V+(P-VT) orV−(N-VT) equivalent to the threshold voltage of the respective diodeconnected FETs 348A, 351A. As shown in FIG. 11A, P-VT 349A includes aTRP diode 348A, RP 348B, RN 348C, and capacitors 347A, 347B. The P-VTreceives clock signals and passes a DC signal between V+ and V−. Thecapacitors 347A, 347B may be about 0.500/1.4/5.362fF/mp=1,3.9/9/211.2fF/mp=1. TRP 348A, 348B may be about 5/0.5/mt=1,1.4/0.5/mt=1, respectively. RN 348C may be about 1.4/0.8/mt=1. RN 351A,351C may be about 5/0.8/mt=1, 1.4/0.5/mt=1, respectively. TRP 351B maybe about 1.4/0.5/mt=1.

As shown in FIG. 11B, N-VT 349B includes an RN diode connected FET 351A,TRP 351B, RN 351C, and capacitors 347A, 347B. The N-VT receives clocksignals and passes DC signal between V− and V+. The P-VT 349A and N-VT349B operate as a diode. The remainder of the elements form switchedcapacitor elements to bias the respective diodes. In N-VT 349B the DCbias is equal to V− plus the threshold of diode 351A and in P-VT 349A,the DC bias is equal to V+ minus the threshold of diode 348A.

FIG. 12 is simplified diagram of a positive voltage control signalgeneration module (VCSGM) 310 according to various embodiments. As shownin FIG. 12, the VCSGM 310 includes an OTA 314, a voltage divider 312, anLDO 317, and a capacitor 318. The OTA includes a CS-N (current sink)formed by TRN 316B pair and a differential amplifier formed by the TRP315A pair and the TRN 316A pair. The OTA 314 may determine thedifference between a reference signal VBG (the output of the BBSGM 100)and voltage divided VDD_LS. In an embodiment VDD_LS is about 3.4 V andVBG is about 1.16 V. The voltage divider 312 includes several resistors311A, 311B where the resistance is selected to make the nominal value ofVDD_LS about equal to VBG (ratio 1.16/3.4 in an embodiment).

In an embodiment the resistor 311A may have a total resistance of about1074.96 Kohms and include at least three resistors in series about13.4/1.4/49.96/ms=2, 13.4/1.4/499.6/ms=20, and 47.2/1.4/525.4/ms=6. Theresistor 311B may have a total resistance of about 562.37 Kohms andinclude at least three resistors in series about 47.2/1.4/175.1/ms=2,13.4/1.4/374.7/ms=15, and 3.3/1.4/6.278/ms=1. Accordingly the resistordivider may reduce the VDD_LS signal by about 65.65% (3.4 V reduced65.65% equals about 1.16 V in an embodiment). The FET TRP 317 may beabout 12/0.4/1. The capacitor 318 may be about 9.65/5.6/321.9F/mp=1. TheFET TRP 315A, TRN 316A, and TRN 316B may be about 4/2/2, 4/2/2, and8/2/1, respectively. The current sink 316C may draw about 2.4 uA in anembodiment.

The LDO (low drop out regulator) formed by the TRP 317 limits or sets aceiling for the POS_CP_VDD control signal. In an embodiment the LDO TRP317 drain can only be high as the source or supply or POS_CP_VDD voltagelevel can only be as great as the VDD_INT voltage level (or about 2.3volts in an embodiment.) As noted below the PVCPGM 340 generates asignal VPOS having a voltage level twice the voltage level ofPOS_CP_VDD. Accordingly during a switching event the PVCPGM 340 VPOSsignal voltage level may be twice the VDD_INT voltage level (or about4.6 volts in an embodiment). Such configuration may enable the BBSGM 100to recover more quickly after a switching event—lowering the potentialinsertion loss of the BBSGM 100. The capacitor 318 may stabilize thePOS_CP_VDD signal in embodiment.

FIG. 13 is simplified diagram of a positive voltage charge pumpgeneration module (PVCPGM) 340 according to various embodiments. Asshown in FIG. 13, the PVCPGM 340 includes P-type voltage trackers (P-VT)349A, N-type voltage trackers (N-VT) 349B, ABR 207, capacitors 341A,341B, 341C upper inverter formed from TRP 353A pair and TRN 353B pair,and lower inverter formed from TRP 353C pair and TRN 353D pair. Thecapacitors 341A, 341B, 341C may be about 4.5/16.45/441fF/mp=1,3.9/9.4/220.5fF/mp=1, 3.9/9.1/213.5fF/mp=1, respectively in anembodiment. The TRP 353A, 353C may be about 12/0.4/mt=1. The TRN 353B,353D may be about 6/0.4/mt=1. The fly capacitors 302A, 302B may be about30/30/5.226pF/mp=1, in an embodiment.

The PVCPGM 340 receives the clock signals OSC1, OSC2, and voltage signalPOS_CP_VDD and alternatively charges and discharges capacitors 302B,302A, respectively to generate signal VPOS. In an embodiment the bottomplate of each capacitor 302A, 302B is at about 1.7 volts (POS_CP_VDD)when discharging, and 0V when charging. During a discharge phase thevoltage at the capacitor 302A, 302B top plate may be about twice thebottom plate voltage level (as supplied by signal POS_CP_VDD (about 1.7volts in an embodiment)) or about 3.4 volts in an embodiment. During thecharging phase these top plates will be at about 1.7 volts (POS_CP_VDD).It is noted that the capacitors 302A, 302B may be MOS capacitors wherethe polarity of the connections is relevant. It is also noted that thePVCPGM may be fully symmetric and the clock signal OSC1, OSC2 may alsobe fully symmetric. As noted in FIG. 13 the P-type voltage tracker 349ADC basis signal B1A is shared by the differential pair 353A through ABR207. Similarly, the N-type voltage tracker 349B DC basis signal B1B isshared by the differential pair 353B through ABR 207.

Similarly on bottom inverter formed from the FET pairs 353C, 353D, theP-type voltage tracker 349A DC basis signal B2A is shared by thedifferential pair 353C through ABR 207. Similarly, the N-type voltagetracker 349B DC basis signal B2B is shared by the differential pair 353Dthrough ABR 207. As noted nominally the voltage level of VPOS is equalto twice the voltage level of POS_CP_VDD. In operation when an inputsignal on OSC1 is high and OSC2 is low, TRP 353 A (right side), TRN 353B(left side), TRP 353C (left side), TRN 353D (right side) are turned onand TRP 353A (left side), TRN 353B (right side), TRP 353C (right side),TRN 353D (left side), are turned off. Similarly, when an input signal onOSC1 is low and OSC2 is high, the opposite is true. The respectivecapacitors 302A, 302B get charged to the level of POS_CP_VDD.Accordingly VPOS is equal to 2×POS_CP_VDD. In an embodiment the PVCPGM340 is symmetrical so clock (DOM 200 ) sees a fully symmetric anddifferential load.

FIGS. 14A-14D are simplified diagrams of a negative voltage controlsignal generation module (NCSGM) 410 according to various embodimentsand the various components. FIG. 15 is simplified diagram of a negativevoltage charge pump generation module (NVCPGM) 440 according to variousembodiments. The NCSGM 410 and NVCPGM 440 is described in co-pending,commonly assigned application PER-027 -PCT, entitled, “LOW-NOISE HIGHEFFICIENCY BIAS GENERATION CIRCUITS AND METHOD”, filed Jul. 17, 2009 andassigned to application number PCT/US2009/004149. As shown in FIG. 14A,the VCSGM 310 includes a buffer 414, a voltage divider 412, an OTA 420,a capacitor bank 416, capacitors 418A, 418B, 418C, a TRP (P-Type FETs)LDO 415 G, N-type FETs 416A and 416B, and a resistors 411A-E. The buffer414 includes a CS-P pair (current source) formed by pair of TRP 415A,415C pair and TRP 415B, 415D pair and TRP 415 E and TRP 415F matchedpair.

In an embodiment the resistor 411A may have a total resistance of about587.53 Kohms and include at least three resistors in series about6.7/1.4/12.57/ ms=1, 13.4/1.4/49.96/ms=2, and 94.4/1.4/525/ms=3. Theresistor 411B may have a total resistance of about 1700.87 Kohms andinclude at least three resistors in series about 94.4/1.4/1575/ms=6,13.5/1.4/100.7/ms=4, and 13.5/1.4/25.17/ms=1. The FETs TRP 415A, 415B,415C, 415D, 415E, 415F may be about 8/4/2 in an embodiment. The FETs TRP415G, 415H may be about 4/0.4/1 and 4/1/1, respectively. The FET TRN416A, 416B may be about 4/1/1 in an embodiment. The FET TRN 417A, 417B,and 417C may be about 20/19.2/1, 20/10/1, and 10/10/1, respectively. Thecapacitors 418A, 418B, and 418C may be about 7/7/292 fF/mp=1,3/5.3/97.39fF/1, and 4/9.6/230.7fF/1, respectively. The resistors 411C,411D, and 411E may be about 62.6/1.4/232.2/ms=2, 62.6/1.4/232.2/ms=2,and 28.3/1.4/630.8/ms=12, respectively.

The capacitor bank 416 may include four TIN type capacitors 418A, 418B,418C, and 418D. The capacitors 418A, 418B, 418C, and 418D may be about20/19.2/mt=1, 20/10/mt=1, 10/10/mt=1, and 5/10/mt=1, respectively. Theincreased capacitor bank 416 may reduce the settling time of the signalVSS after a switching event. The switch 416B may also prevent thecapacitor bank 416 from discharging or limits its discharge during aswitching event. The switch 416B may also help reduce the settling timeof the signal VSS after a switching event.

FIG. 14B is a simplified diagram of an OTA 420 according to variousembodiments and the various components that may be employed in the NCSGM410 shown in FIG. 14A. As shown in FIG. 14B, the OTA 420 may include anOTA Tune 460, two OTA 430, a clamp 422A, a clamp 422B, capacitors 427A,427B, and resistors 428A and 428B. The clamp 422A includes a CS-P(current source) 142 including a FET TRP pair 423A, 423B, a bufferformed by TRP 423C, and diode connected FETs TRP 423D and 423 E. Theclamp 422B includes a CS-N (current sink) 172 including a FET TRN pair425A, 425B, a buffer formed by TRP 423 G, and diode connected FETs TRP423F and 423H.

The FETs TRP 423A, 423B may be about 4/2/1 so the CS-P 142 may provideabout 1.2 uA of current in an embodiment. The FETs TRP 423C, 423D, 423H,423 G may be about 4/1.8/1 in an embodiment. The FETs TRP 423E, 423F maybe about 4/0.4/1 in an embodiment. The capacitors 427A, 427B may beabout 10.5/4.9/307.1fF/mp=1. The resistors 428A and 428B may be about26.9/1.4/99.96/ms=2 and 26.9/1.4/199.9/ms=4, respectively.

FIG. 14C is a simplified diagram of an OTA Tune 460 according to variousembodiments and the various components that may be employed in the OTA420 shown in FIG. 14B. As shown in FIG. 14C, the OTA Tune 460 mayinclude a first differential OTA 462A, a second differential OTA 462B, aTRP pair 465C, 465D, and a TRP 465G. The first differential OTA 462A mayinclude a CS-N (current sink) 172 including a FET TRN pair 463A, 463B(and receiving the gate bias signals BIASN1, BIASN2), and amplifierformed by TRP pair 465A, 465B, TIN pair 464A, 464B, and a TIN pair 464C,464D. The second differential OTA 462B may include a CS-N (current sink)172 including a FET TRN pair 463C, 463D (and receiving the gate biassignals BIASN1, BIASN2 ), and an amplifier formed by TRP pair 465E,465F, TIN pair 464E, 464G, and a TIN pair 464F, 464H.

Both differential OTAs 462A, 462B compare the signals INP_BIAS andINN_BIAS and INP and INN in opposite polarities. The first differentialOTA 462A generates the signal OUTP having a floor controlled by CM_TUNEand the TRP pair 465C, 465D. The second differential OTA 462B generatesthe signal OUTN having a floor controlled by CM_TUNE and the TRP 465Cand 465G. The FETs TRN 463A, 463B, 463C, 463D may be about 8/2/1 so eachtwo CS-N 172 may draw about 2.4 uA of current in an embodiment. The FETsTIN 464C, 464D, 464 F, 464H may be about 4/2/2 in an embodiment. TheFETs TIN 464A, 464B, 464 E, 464G may be about 4/1/1 in an embodiment.The FETs TRP 465A, 465E may be about 4/1/2 in an embodiment. The FETsTRP 465B, 465F may be about 4/1/1 in an embodiment. The FETs TRP 465D,465G may be about 4/1/3 in an embodiment. The FET TRP 465C may be about4/0.5/1 in an embodiment.

FIG. 14D is a simplified diagram of an OTA 430 according to variousembodiments and the various components that may be employed in the OTA420 shown in FIG. 14B. As shown in FIG. 14D, the OTA 430 may be adifferential OTA and include a CS-N (current sink) 172 including a FETTRN pair 434C, 434D (and receiving the gate bias signals BIASN1, BIASN2), and an amplifier formed by TRP pair 432A, 432B, and a TRN pair 434A,434B. The differential OTA 430 may compare the signals INP and INN andgenerate the signal OUT based on said differential. The FETs TRN 434C,434D may be about 4/2/1 so the CS-N 172 may draw about 1.2 uA of currentin an embodiment. The FETs TRN 434A, 434B may be about 4/2/1 in anembodiment. The FETs TRP 432A, 432B may be about 4/2/1 in an embodiment.

FIG. 15 is simplified diagram of a negative voltage charge pumpgeneration module (NVCPGM) 440 according to various embodiments. Asshown in FIG. 15, the NVCPGM 440 includes P-type voltage trackers (P-VT)349A, N-type voltage trackers (N-VT) 349B, ABR 207, capacitors 441A,441B, 441C, 441D, 441E, 441F, upper inverter formed from TRP 453A pairand TRN 453B pair, lower inverter formed from TRP 453C pair and TRN 453Dpair, TRP 453E, 453F, 453G, 453I, IP 453H, 453J. External fly capacitors402A, 402B, and 403C are coupled to the inverters. In an embodiment thecapacitors 441A, 441B, 441C, 441D, 441E, 441F may be about10/12/706.61F/mp=1, 5.9/10.2/357.9fF/mp=1, 6.9/6/247.5F/mp=1,6.9/6/247.5fF/mp=1, 14.8/12/2.084pF/mp=2, and 9.65/12/1.364 pF/mp=2,respectively in an embodiment. The TRP 453A, 453C may be about20/0.35/mt=1. The TRN 453B, 453D may be about 10/0.35/mt=1. The flycapacitors 402A, 402B, 402C may be about 30/30/5.226pF/mp=1, in anembodiment. The TRP 453E, 453F, 453G, 453I may be about 1.4/0.8/mt=1.The IP 453H, 453J may be about 1.4/0.8/mt=1 in an embodiment.

The NVCPGM 440 receives the clock signals OSC1, OSC2, and voltage signalNEG_CP_VDD and alternatively charges and discharges capacitors 402A and402B, 402C pair, respectively to generate signal VNEG. In operation,when an input signal on OSC1 is high and OSC2 is low, TRN 453B (leftside), 453D (right side), TRP 453A (right side), 453C (left side), areturned on and TRN 453B (right side), 453D (left side), TRP 453A (leftside), 453C (right side)are turned off. Similarly, when an input signalon OSC1 is low and OSC2 is high, everything is reversed. The capacitors402A, 402B and 402C get charged to the level of NEG_CP_VDD. AccordinglyVNEG is equal to −(2×NEG_CP_VDD) or about −3.4 Volts in an embodiment.In an embodiment the NVCPGM 440 is symmetrical so clock (DOM 200 ) seesa fully symmetric and differential load.

The length of the FET TRP 453A, 453C and TRN 453B, 453D may be about0.35 um versus 0.4 um in another embodiment to reduce the drop acrossthese devices. In an embodiment the capacitor 402A may include 10coupled 30/30/5.226pF/mp=1 capacitors, the capacitor 402B may include 8coupled 30/30/5.226pF/mp=1 capacitors, and the capacitor 402C mayinclude 8 coupled 30/30/5.226pF/mp=1. In another embodiment theembodiment the capacitor 402A may include 4 coupled 30/30/5.226p/mp=1capacitors, the capacitor 402B may include 4 coupled 30/30/5.226pF/mp=1capacitors, and the capacitor 402C may include 4 coupled30/30/5.226p/mp=1. Such configurations may reduce the VSS settling timeafter a switching event.

Reference Table for Specification: BSGA Bias Signal GenerationArchitecture 10 BBSGM Base Bias Signal Generation Module 100 DOMDifferential Oscillator Module 200 PVCPM Positive Voltage Charge PumpModule 300 NVCPM Negative Voltage Charge Pump Module 400 PVCM PositiveVoltage Clamping Module 15 NVCM Negative Voltage Clamping Module 17 PSMPower Supply Module 18 VRM Voltage Regulator Module 110 BRM BandgapReference Module 140 RVCGM Reference Voltage and Current GeneratorModule 170 SSM Startup and Standby Module 190 VDD External power supplysignal VDD_LS Positive Voltage Supply VNEG Negative Voltage Supply GNDGround BIASP1 Bias Signal 1 for P-type devices BIASP2 Bias Signal 2 forP-type devices BIASN1 Bias Signal 1 for N-type devices BIASN2 BiasSignal 2 for N-type devices VBG Bandgap voltage reference signal HKPHarmonic Knee Point FET field-effect transistor CS_P current sourceP-type CS_N current sink N-type OPAMP operational amplifiers OTAoperational trans-conductance amplifiers POS_CP_VDD positive charge pumpcontrol signal NEG_CP_VDD negative charge pump control signal LDO lowdrop out TIN thicker film intrinsic N-type FET IN intrinsic N-type FETTRP thicker film regular type P-type FET TRN thicker film regular typeN-type FET RP regular type P-type FET RN regular type N-type FET IREFreference current IVREF reference voltage based on reference currentCBVGM current/bias voltage generation module 192 ABR active biasresistor 207 VCSGM positive voltage control signal generation module 310PVCPGM positive voltage charge pump generation module 340 NCSGM negativecontrol signal generation module 410 NVCPGM negative voltage charge pumpgeneration module 440 P_VT P-type voltage tracker 349A N_VT N-typevoltage tracker 349B

The apparatus and systems of various embodiments may be useful inapplications other than a sales architecture configuration. They are notintended to serve as a complete description of all the elements andfeatures of apparatus and systems that might make use of the structuresdescribed herein. It is noted that the bias signal generationarchitecture (“BSGA”) 10 may be formed in whole or part on silicon oninsulator (SOI) wafer(s) including silicon on sapphire (SOS) accordingto various embodiments. Any or all of the base bias signal generatormodule (“BBSGM”) 100, the differential oscillator module (“DOM”) 200,the positive voltage charge pump module (“PVCPM”) 300, the negativevoltage charge pump module (“NVCPM”) 400, the positive voltage clampingmodule (“PVCM”) 15, the negative voltage clamping module (“NVCM”) 17,and the switching module 22 may be formed in whole or part on silicon oninsulator (SOI) wafer(s) including silicon on sapphire (SOS) accordingto various embodiments.

Applications that may include the novel apparatus and systems of variousembodiments include electronic circuitry used in high-speed computers,communication and signal processing circuitry, modems, single ormulti-processor modules, single or multiple embedded processors, dataswitches, and application-specific modules, including multilayer,multi-chip modules. Such apparatus and systems may further be includedas sub-components within a variety of electronic systems, such astelevisions, cellular telephones, personal computers (e.g., laptopcomputers, desktop computers, handheld computers, tablet computers,etc.), workstations, radios, video players, audio players (e.g., mp3players), vehicles, medical devices (e.g., heart monitor, blood pressuremonitor, etc.) and others. Some embodiments may include a number ofmethods.

It may be possible to execute the activities described herein in anorder other than the order described. Various activities described withrespect to the methods identified herein can be executed in repetitive,serial, or parallel fashion.

A software program may be launched from a computer-readable medium in acomputer-based system to execute functions defined in the softwareprogram. Various programming languages may be employed to createsoftware programs designed to implement and perform the methodsdisclosed herein. The programs may be structured in an object-orientatedformat using an object-oriented language such as Java or C++.Alternatively, the programs may be structured in a procedure-orientatedformat using a procedural language, such as assembly or C. The softwarecomponents may communicate using a number of mechanisms well known tothose skilled in the art, such as application program interfaces orinter-process communication techniques, including remote procedurecalls. The teachings of various embodiments are not limited to anyparticular programming language or environment.

The accompanying drawings that form a part hereof show, by way ofillustration and not of limitation, specific embodiments in which thesubject matter may be practiced. The embodiments illustrated aredescribed in sufficient detail to enable those skilled in the art topractice the teachings disclosed herein. Other embodiments may beutilized and derived there-from, such that structural and logicalsubstitutions and changes may be made without departing from the scopeof this disclosure. This Detailed Description, therefore, is not to betaken in a limiting sense, and the scope of various embodiments isdefined only by the appended claims, along with the full range ofequivalents to which such claims are entitled.

Such embodiments of the inventive subject matter may be referred toherein individually or collectively by the term “invention” merely forconvenience and without intending to voluntarily limit the scope of thisapplication to any single invention or inventive concept, if more thanone is in fact disclosed. Thus, although specific embodiments have beenillustrated and described herein, any arrangement calculated to achievethe same purpose may be substituted for the specific embodiments shown.This disclosure is intended to cover any and all adaptations orvariations of various embodiments. Combinations of the aboveembodiments, and other embodiments not specifically described herein,will be apparent to those of skill in the art upon reviewing the abovedescription.

The Abstract of the Disclosure is provided to comply with 37 C.F.R.§1.72 (b), requiring an abstract that will allow the reader to quicklyascertain the nature of the technical disclosure. It is submitted withthe understanding that it will not be used to interpret or limit thescope or meaning of the claims. In the foregoing Detailed Description,various features are grouped together in a single embodiment for thepurpose of streamlining the disclosure. This method of disclosure is notto be interpreted to require more features than are expressly recited ineach claim. Rather, inventive subject matter may be found in less thanall features of a single disclosed embodiment. Thus the following claimsare hereby incorporated into the Detailed Description, with each claimstanding on its own as a separate embodiment.

What is claimed is:
 1. An apparatus for generating a substantiallysteady state positive voltage signal (PVS) and a substantially steadystate negative voltage signal (NVS) to a switching module (SM), the PVSand the NVS remaining substantially stable during a switching event ofthe SM, including: a bias signal generation module (BSGM) for generatinga substantially steady state reference voltage signal (RVS), the RVShaving a voltage level nominally less than the PVS; a positive signalgeneration module (PSGM) generating the PVS, the PSGM including a firstcapacitor, the PSGM employing the first capacitor to nominally generatea portion of the PVS based on the RVS; and a negative signal generationmodule (NSGM) generating the NVS, the NSGM including a second capacitor,the NSGM employing the second capacitor to nominally generate a portionof the NVS based on the RVS.
 2. The apparatus of claim 1, wherein the SMmodulates a radio frequency (RF) signal.
 3. The apparatus of claim 1,the PSGM generating a positive capacitor control signal (PCCS) based atleast partially on the RVS and employing the first capacitor tonominally generate a portion of the PVS at least partially based on thePCCS.
 4. The apparatus of claim 1, the NSGM generating a negativecapacitor control signal (NCCS) based at least partially on the RVS andemploying the second capacitor to nominally generate a portion of theNVS at least partially based on the NCCS.
 5. The apparatus of claim 1,the BSGM employing a first FET element and a second FET element formedon a common silicon on insulator (SOI) wafer in part to generate the RVSwhere the RVS is temperature independent.
 6. The apparatus of claim 3,wherein the ratio of the PVS voltage magnitude to the RVS voltagemagnitude is about 1.5 to
 4. 7. The apparatus of claim 6, wherein theratio of the NVS voltage magnitude to the RVS voltage magnitude is about1.5 to
 4. 8. The apparatus of claim 1, the BSGM further generating afirst field effect transistor (FET) bias signal and a second FET biassignal, the PSGM at least employing the first FET bias signal, and theNSGM at least employing the second FET bias signal.
 9. The apparatus ofclaim 8, wherein the PSGM employs the first FET bias signal at leastpartially to generate a current drain.
 10. The apparatus of claim 9,wherein the NSGM employs the second FET bias signal at least partiallyto generate a current source.
 11. The apparatus of claim 9, wherein thePSGM includes a differential module, the differential module employingthe current drain and determining a differential between the PVS signalvoltage level and the RVS voltage level.
 12. The apparatus of claim 10,wherein the NSGM includes a differential module, the differential moduleemploying the current source and determining a differential between theNVS signal voltage level and the RVS voltage level.
 13. The apparatus ofclaim 2, wherein the BSGM generates an internal, substantially stable,voltage signal (IVS) based on at least partially on the first FET biassignal and the RVS.
 14. The apparatus of claim 13, wherein the PSGMgenerates the PVS in part with the IVS.
 15. The apparatus of claim 14,wherein the NSGM generates the NVS in part with the IVS.
 16. Theapparatus of claim 13, wherein the PSGM employs the first capacitor tonominally generate about half of the voltage level of the PVS.
 17. Theapparatus of claim 16, wherein the NSGM employs the second capacitor tonominally generate about half of the magnitude of the voltage level ofthe NVS.
 18. A method of generating a substantially steady statepositive voltage signal (PVS) and a substantially steady state negativevoltage signal (NVS) to a switching module (SM), the PVS and the NVSremaining substantially stable during a switching event of the SM,including: generating a substantially steady state reference voltagesignal (RVS), the RVS having a voltage level nominally less than thePVS; employing a first capacitor to nominally generate a portion of thePVS based on the RVS; and employing a second capacitor to nominallygenerate a portion of the NVS based on the RVS.
 19. The method of claim18, wherein the SM modulates a radio frequency (RF) signal.
 20. Themethod of claim 18, further including generating a positive capacitorcontrol signal (PCCS) based at least partially on the RVS and employingthe first capacitor to nominally generate a portion of the PVS at leastpartially based on the PCCS.
 21. The method of claim 20, furtherincluding generating a negative capacitor control signal (NCCS) based atleast partially on the RVS and employing the second capacitor tonominally generate a portion of the NVS at least partially based on theNCCS.
 22. The method of claim 18, further including employing a firstFET element and a second FET element formed on a common silicon oninsulator (SOI) wafer in part to generate the RVS where the RVS istemperature independent.
 23. The method of claim 20, wherein the ratioof the PVS voltage magnitude to the RVS voltage magnitude is about 1.5to
 4. 24. The method of claim 23, wherein the ratio of the NVS voltagemagnitude to the RVS voltage magnitude is about 1.5 to
 4. 25. The methodof claim 18, further including generating a first field effecttransistor (FET) bias signal and a second FET bias signal.
 26. Themethod of claim 25, further including employing the first FET biassignal at least partially to generate a current drain.
 27. The method ofclaim 26, further including employing the second FET bias signal atleast partially to generate a current source.
 28. The method of claim26, further including employing the current drain in part to determine adifferential between the PVS signal voltage level and the RVS voltagelevel.
 29. The method of claim 27, further including employing thecurrent source in part to determine a differential between the NVSsignal voltage level and the RVS voltage level.
 30. The method of claim19, further including generating an internal, substantially stable,voltage signal (IVS) based on at least partially on the first FET biassignal and the RVS.
 31. The method of claim 30, further includinggenerating the PVS in part with the IVS.
 32. The method of claim 31,further including generating the PVS in part with the IVS.
 33. Themethod of claim 13, further including employing the first capacitor tonominally generate about half of the voltage level of the PVS.
 34. Themethod of claim 33, further including employing the second capacitor tonominally generate about half of the magnitude of the voltage level ofthe NVS.